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Polysaccharide is a major constituent of the total organic carbon that is generated by photosynthetic eukaryotes. In the marine realm, where approximately half of annual global carbon fixation occurs, algae can produce large amounts of polysaccharide during bloom events. Phytoplankton blooms are frequently seasonal phenomena, and spring blooms in particular have been a focus of study as they are predictable in space and time. This makes them much more amenable model systems in which to explore the processes that occur as organic carbon is recycled.
It is assumed that the bulk of the polysaccharides algae produce serve one of two primary functions - namely acting as an energy storage molecule, or they serve as structural polymers in the cell walls. Other polysaccharides may also have protective functions as exudates. Regardless of function in algae, the polysaccharides are a valuable energy source for heterotrophic bacteria. The combination of abundance and predictable or semi-predictable structure of the polysaccharides has led to proliferation of variations on a particular sequestration and degradation strategy among the Bacteroidetes and Gammaproteobacteria that is frequently characterised as being ‘selfish’. The strategy is based on uptake of poly- and especially oligosaccharides into the periplasm via the use of TonB-dependent transporters. Once in the periplasmic space, oligomers can be further degraded to monomers that can then be transported into the cytosol. This mechanism is beneficial to the cell as it needn’t then lose the nutritive benefit of the polysaccharide to other cells, which may or may not have manufactured their own degradative carbohydrate active enzymes (CAZymes).
The research articles that make up this thesis are thus based around attempts to find and elucidate the polysaccharide preferences of heterotrophic bacteria that become abundant following phytoplankton blooms.The first article is a study into the abundance of TonB-dependent transporter proteins in metaproteomes and metagenomes across a single spring phytoplankton bloom at the long term research station at Helgoland. This investigation identifies transporters for laminarin and alpha-glucans, the two most abundant glucose-based storage polysaccharides, are the most abundant predicted polysaccharide transporting TonB-dependent transporters during the bloom. However, as the bloom progressed, and particularly following a doubling of bacterial cell numbers, the proportion of predicted polysaccharide transporters dedicated to laminarin and alpha-glucan transport declined relative to transporters for less readily degraded mannose-, xylose-, and fucose-containing polysaccharides. The inference is that this change is an active response to the availability of the different polysaccharides, or their relative attractiveness as growth substrates during the period.
The second article is an in-depth look at one of the most abundant Bacteroidetes clades, which was previously unnamed, and has not to date been cultivated. The most abundant species in this clade grows rapidly and often peaks earlier than other heterotrophic clades. It was found to be limited in predicted polysaccharide consumption capability, having only PULs for predicted laminarin degradation. It is also detectable in many locations at higher latitudes where phytoplankton blooms are expected to occur, indicating this is a globally successful consumer of algal organic matter, and may have an outsize significance for global laminarin degradation given its high abundance.
The third article is a more holistic study of phytoplankton bloom associated Gammaproteobacteria, which have otherwise been rather ignored compared to the Bacteroidetes. Gammaproteobacteria overlap with Bacteroidetes to some extent in being clear consumers of laminarin, but fewer of them are clearly capable of consuming the more complex cell-wall derived polysaccharides. Some may, however, be producers of alginate, an otherwise mysteriously popular polysaccharide with Bacteroidetes, given that it is not known to be produced by bloom forming microalgae.
The fourth article then goes into detail on the PUL content of Bacteroidetes, based on metagenomic data. It finds five substrates, alpha- and beta-glucans, xylose and mannose rich polysaccharides, and alginate, are the most frequent predicted polysaccharide substrates for Bacteroidetes PULs among populations responding to the Helgoland spring blooms.
This thesis thus summarises multiple metagenomic and metaproteomic investigations into the polysaccharide consumption capabilities of marine heterotrophic bacteria. These bacteria have a profound impact on the overall carbon cycle in coastal regions, and are critical for understanding how changes in atmospheric carbon concentrations impact carbon turnover and storage in the world's oceans.