Delineation of ecologically distinct units of marine Bacteroidetes in the Northwestern Mediterranean Sea

Díez‐Vives, Cristina; Nielsen, Shaun; Sánchez, Pablo; Palenzuela, Oswaldo; Ferrera, Isabel; Sebastián, Marta; Pedrós‐Alió, Carlos; Gasol, Josep M.; Acinas, Silvia G.

doi:10.1111/mec.15068

Cited by 27 publications

(18 citation statements)

References 91 publications

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“…The resulting tree indicated that the NAAMES ASVs clustered into three distinct clades, and each of these clades included at least one closely related SAG for genome comparison (Figure 5). The phylogenetic placement of the NAAMES flavobacteria ASVs is consistent with previous research that has indicated that there is a high degree of niche specialization amongst these organisms (Diez-Vives et al, 2019). The SAGs were then queried for B1 synthesis capacity.…”

Section: Stations 1 and 2 Have Contrasting Relationships Between Trcssupporting

confidence: 76%

Exploring Vitamin B1 Cycling and Its Connections to the Microbial Community in the North Atlantic Ocean

et al. 2020

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Vitamin B1 (thiamin) is an essential coenzyme for all cells. Recent findings from experimental cell biology and genome surveys have shown that thiamin cycling by plankton is far more complex than was previously understood. Many plankton cells cannot produce thiamin (are auxotrophic) and obligately require an exogenous source of thiamin or one or more of 5 different thiamin-related compounds (TRCs). Despite this emerging evidence for the evolution among plankton of complex interactions related to thiamin, the influence of TRCs on plankton community structure and productivity are not understood. We report measurements of three dissolved TRCs 4-amino-5-aminomethyl-2-methylpyrimidine (AmMP), 5-(2-hydroxyethyl)-4-methyl-1,3-thiazole-2-carboxylic acid (cHET), and 4-methyl-5-thiazoleethanol (HET) that have never before been assayed in seawater. Here we characterize them alongside other TRCs that were measured previously [thiamin and 4-amino-5-hydroxymethyl-2-methylpyrimidine (HMP)], in depth profiles from a latitudinal transect in the north Atlantic in March 2018. TRC concentrations ranged from femptomolar to picomolar. Surface depletion relative to a maximum near the bottom of the euphotic zone and low concentrations at deeper depths were consistent features. Our observations suggest that when bacterial abundance and production are low, TRC concentrations approach a steady state where TRC production and consumption terms are balanced. Standing stocks of TRCs also appear to be positively correlated with bacterial production. However, near the period of peak biomass in the accumulation phase of a bloom we observed an inverse relationship between TRCs and bacterial production, coincident with an increased abundance of Flavobacteria that comparative genomics indicates could be vitamin B1 auxotrophs. While these observations suggest that the dissolved pool of TRCs is often at steady state, with TRC production and consumption balanced, our data suggests that bloom induced shifts in microbial community structure and activity may cause a decoupling between TRC production and consumption, leading to increased abundances of some populations of bacteria that are putatively vitamin B1 auxotrophs.

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Section: Stations 1 and 2 Have Contrasting Relationships Between Trcssupporting

confidence: 76%

Exploring Vitamin B1 Cycling and Its Connections to the Microbial Community in the North Atlantic Ocean

et al. 2020

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“…Among the non-shared Bacteroidetes genera or groups, the NS5 marine group, Polaribacter, Pseudarcicella, and Fluviicola (a typical freshwater genus) characterized water samples, whereas Lutimonas and Maribacter were retrieved in sediments. A number of authors have reported on the dominance of flavobacterial phylotypes responding to phytoplankton blooms, with the succession of particular clades (including Ulvibacter spp., Polaribacter spp., and NS5 marine clades) and the progressive consumption of the algal-derived organic matter [44,45]. In this study, the NS5 marine group was found at very high percentages, also at inner stations, and its co-occurrence with some clades cited above was especially evident at the middle station 9w, suggesting that an algal bloom was present at sampling time.…”

Section: Discussionsupporting

confidence: 52%

Bacterial Diversity in a Dynamic and Extreme Sub-Arctic Watercourse (Pasvik River, Norwegian Arctic)

Papale

Rappazzo

Mikkonen

et al. 2020

Water

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Microbial communities promptly respond to the environmental perturbations, especially in the Arctic and sub-Arctic systems that are highly impacted by climate change, and fluctuations in the diversity level of microbial assemblages could give insights on their expected response. 16S rRNA gene amplicon sequencing was applied to describe the bacterial community composition in water and sediment through the sub-Arctic Pasvik River. Our results showed that river water and sediment harbored distinct communities in terms of diversity and composition at genus level. The distribution of the bacterial communities was mainly affected by both salinity and temperature in sediment samples, and by oxygen in water samples. Glacial meltwaters and runoff waters from melting ice probably influenced the composition of the bacterial community at upper and middle river sites. Interestingly, marine-derived bacteria consistently accounted for a small proportion of the total sequences and were also more prominent in the inner part of the river. Results evidenced that particular conditions occurring at sampling sites (such as algal blooms, heavy metal contamination and anaerobiosis) may select species at local scale from a shared bacterial pool, thus favoring certain bacterial taxa. Conversely, the few phylotypes specifically detected in some sites are probably due to localized external inputs introducing allochthonous microbial groups.

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“…Bacteroidetes, globally distributed in human gut, coastal ocean, marine sediments and other environments, play key roles in the degradation of high molecular weight carbohydrates ( Cottrell Kirchman, 2000; Fernandez-Gomez et al, 2013; Thomas et al, 2011 ). As such, Bacteroidetes are recognized as one of the dominant phyla of ocean bacterioplankton ( Diez-Vives et al, 2019 ) and are the most important decomposer for algae derived carbohydrates, actively driving the ocean carbon and nutrient cycling ( Kruger et al, 2019; Unfried et al, 2018 ). As compared to studies of Bacteroidetes derived from the shallow ocean, very little research has been done on the deep-sea counterparts, likely due to the difficulties of sampling and cultivation.…”

Section: Discussionmentioning

confidence: 99%

Bacteroidetes contribute to the carbon and nutrient cycling of deep sea through breaking down diverse glycans

Zheng

Cai

et al. 2020

Preprint

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Bacteroidetes are thought to be specialized for the degradation of algae-derived ocean polysaccharides and are a major contributor to the marine carbon and nutrient cycling. Here, we first show Bacteroidetes are the second most abundant phylum bacteria in deep-sea cold seep and possess more genes associated with polysaccharides degradation than other bacteria through metagenomics methods. We further isolate a novel Bacteroidetes species, Maribellus comscasis WC007T, which can efficiently degrade numerous different polysaccharides including: cellulose, pectin, fucoidan, mannan, xylan and starch. These results are verified by transcriptomic analyses and growth assays. Notably, we find cellulose promotes abundant bacterial growth, and using transcriptomics and metabolomics we finally report on the underlying mechanisms of cellulose degradation and utilization, as well as potential contributions to the carbon cycling. Overall, our results suggest Bacteroidetes play key roles in the deep-sea carbon and nutrient cycling, likely due to their high abundance and prominent polysaccharide degradation capabilities.

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Delineation of ecologically distinct units of marine Bacteroidetes in the Northwestern Mediterranean Sea

Cited by 27 publications

References 91 publications

Exploring Vitamin B1 Cycling and Its Connections to the Microbial Community in the North Atlantic Ocean

Exploring Vitamin B1 Cycling and Its Connections to the Microbial Community in the North Atlantic Ocean

Bacterial Diversity in a Dynamic and Extreme Sub-Arctic Watercourse (Pasvik River, Norwegian Arctic)

Bacteroidetes contribute to the carbon and nutrient cycling of deep sea through breaking down diverse glycans

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