Tanja Fischer scite author profile

Polysaccharide degradation by heterotrophic microbes is a key process within Earth’s carbon cycle. Here, we use environmental proteomics and metagenomics in combination with cultivation experiments and biochemical characterizations to investigate the molecular details of in situ polysaccharide degradation mechanisms during microalgal blooms. For this, we use laminarin as a model polysaccharide. Laminarin is a ubiquitous marine storage polymer of marine microalgae and is particularly abundant during phytoplankton blooms. In this study, we show that highly specialized bacterial strains of the Bacteroidetes phylum repeatedly reached high abundances during North Sea algal blooms and dominated laminarin turnover. These genomically streamlined bacteria of the genus Formosa have an expanded set of laminarin hydrolases and transporters that belonged to the most abundant proteins in the environmental samples. In vitro experiments with cultured isolates allowed us to determine the functions of in situ expressed key enzymes and to confirm their role in laminarin utilization. It is shown that laminarin consumption of Formosa spp. is paralleled by enhanced uptake of diatom-derived peptides. This study reveals that genome reduction, enzyme fusions, transporters, and enzyme expansion as well as a tight coupling of carbon and nitrogen metabolism provide the tools, which make Formosa spp. so competitive during microalgal blooms.

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Biopearling of Interconnected Outer Membrane Vesicle Chains by a Marine Flavobacterium

Fischer

Schorb²,

Reintjes

et al. 2019

Appl Environ Microbiol

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Large surface-to-volume ratios provide optimal nutrient uptake conditions for small microorganisms in oligotrophic habitats. The surface area can be increased with appendages. Here, we describe chains of interconnecting vesicles protruding from cells of strain Hel3_A1_48, affiliating with Formosa spp. within the Flavobacteriia and originating from coastal free-living bacterioplankton. The chains were up to 10 μm long and had vesicles emanating from the outer membrane with a single membrane and a size of 80 to 100 nm by 50 to 80 nm. Cells extruded membrane tubes in the exponential phase, whereas vesicle chains dominated on cells in the stationary growth phase. This formation is known as pearling, a physical morphogenic process in which membrane tubes protrude from liposomes and transform into chains of interconnected vesicles. Proteomes of whole-cell membranes and of detached vesicles were dominated by outer membrane proteins, including the type IX secretion system and surface-attached peptidases, glycoside hydrolases, and endonucleases. Fluorescein-labeled laminarin stained the cells and the vesicle chains. Thus, the appendages provide binding domains and degradative enzymes on their surfaces and probably storage volume in the vesicle lumen. Both may contribute to the high abundance of these Formosa-affiliated bacteria during laminarin utilization shortly after spring algal blooms. IMPORTANCE Microorganisms produce membrane vesicles. One synthesis pathway seems to be pearling that describes the physical formation of vesicle chains from phospholipid vesicles via extended tubes. Bacteria with vesicle chains had been observed as well as bacteria with tubes, but pearling was so far not observed. Here, we report the observation of, initially, tubes and then vesicle chains during the growth of a flavobacterium, suggesting biopearling of vesicle chains. The flavobacterium is abundant during spring bacterioplankton blooms developing after algal blooms and has a special set of enzymes for laminarin, the major storage polysaccharide of microalgae. We demonstrated with fluorescently labeled laminarin that the vesicle chains bind laminarin or contain laminarin-derived compounds. Proteomic analyses revealed surface-attached degradative enzymes on the outer membrane vesicles. We conclude that the large surface area and the lumen of vesicle chains may contribute to the ecological success of this marine bacterium.

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Genomic and physiological analyses of ‘Reinekea forsetii’ reveal a versatile opportunistic lifestyle during spring algae blooms

Avcı

Hahnke

Chafee

et al. 2017

Environmental Microbiology

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Gammaproteobacterial Reinekea spp. were detected during North Sea spring algae blooms in the years 2009-2012, with relative abundances of up to 16% in the bacterioplankton. Here, we explore the ecophysiology of 'R. forsetii' strain Hel1_31_D35 that was isolated during the 2010 spring bloom using (i) its manually annotated, high-quality closed genome, (ii) re-analysis of in situ data from the 2009-2012 blooms and (iii) physiological tests. High resolution analysis of 16S rRNA gene sequences suggested that 'R. forsetii' dominated Reinekea populations during these blooms. This was corroborated by retrieval of almost complete Hel1_31_D35 genomes from 2009 and 2010 bacterioplankton metagenomes. Strain Hel1_31_D35 can use numerous low-molecular weight substrates including diverse sugar monomers, and few but relevant algal polysaccharides such as mannan, α-glucans, and likely bacterial peptidoglycan. It oxidizes thiosulfate to sulfate, and ferments under anoxic conditions. The strain can attach to algae and thrives at low phosphate concentrations as they occur during blooms. Its genome encodes RTX toxin and secretion proteins, and in cultivation experiments Hel1_31_D35 crude cell extracts inhibited growth of a North Sea Polaribacter strain. Our data suggest that the combination of these traits make strain Hel1_31_D35 a versatile opportunist that is particularly competitive during spring phytoplankton blooms.

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Tanja Fischer

Adaptive mechanisms that provide competitive advantages to marine bacteroidetes during microalgal blooms

Biopearling of Interconnected Outer Membrane Vesicle Chains by a Marine Flavobacterium

Genomic and physiological analyses of ‘Reinekea forsetii’ reveal a versatile opportunistic lifestyle during spring algae blooms

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