Structure and function of high Arctic pelagic, particle‐associated and benthic bacterial communities

Balmonte, John Paul; Teske, Andreas; Arnosti, Carol

doi:10.1111/1462-2920.14304

Cited by 40 publications

(62 citation statements)

References 72 publications

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“…4b, Supplementary Table S6) independent of sampling depth and location. Specifically, there was no indication that obligate benthic species [36][37][38] (e.g. JTB255) were present among the sheath-water bacteria, whilst the dominant identified taxa (e.g.…”

Section: Resultsmentioning

confidence: 96%

Bacterioplankton reveal years-long retention of Atlantic deep-ocean water by the Tropic Seamount

Giljan

Kamennaya

Otto³

et al. 2020

Sci Rep

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Seamounts, often rising hundreds of metres above surrounding seafloor, obstruct the flow of deepocean water. While the retention of deep-water by seamounts is predicted from ocean circulation models, its empirical validation has been hampered by large scale and slow rate of the interaction. to overcome these limitations we use the growth of planktonic bacteria to assess the retention time of deep-ocean water by a seamount. the selected tropic Seamount in the north-eastern Atlantic is representative for the majority of isolated seamounts, which do not affect the surface ocean waters. We prove deep-water is retained by the seamount by measuring 2.4× higher bacterial concentrations in the seamount-associated or 'sheath'-water than in deep-ocean water unaffected by seamounts. Genomic analyses of flow-sorted, dominant sheath-water bacteria confirm their planktonic origin, whilst proteomic analyses of the sheath-water bacteria, isotopically labelled in situ, indicate their slow growth. According to our radiotracer experiments, it takes the sheath-water bacterioplankton 1.5 years to double their concentration. therefore, the seamount should retain the deep-ocean water for 1.8 years for the deep-ocean bacterioplankton to grow to the 2.4× higher concentration in the sheathwater. We propose that turbulent mixing of the seamount sheath-water stimulates bacterioplankton growth by increasing cell encounter rate with ambient dissolved organic molecules.The 1,000-year-long global thermohaline circulation 1 connects the bulk deep water of the modern World Ocean, irrespective of barriers erected by continents, islands and thousands of seamounts 2-4 . While continents and islands shape the circulation, seamounts affect this deep-water flow by creating enclosed circulation cells 5 , thereby reducing exchange between the so-called 'sheath-water' retained by seamounts and the surrounding deep water.This does not, however, mean that the sheath-water is stagnant. The interaction of seamounts with deep water currents and waves (internal and tidal) causes complex sheath-water dynamics 6 , specified by the unique geometry of individual seamounts 5 . The complexity arises from interactions of parallel, rapid, turbulent mixing at centimetre-scales on seamount slopes 7,8 and much slower flowing circulations (including Taylor columns) at the seamount-scale 9 . The complex sheath-water dynamics shapes seamount habitats for resident benthos and plankton 5,10,11 , causes erosion, controls sedimentation and affects ferromanganese crust formation on seamount slopes 12 .A number of seamounts peak close to the ocean surface and mix nutrient-rich deep water with the nutrient-poor surface water enhancing local phytoplankton growth 13 and causing a surface seamount effect 5,13,14 ; retention of the produced organic matter in the seamount proximity raises productivity and enriches diversity of the entire seamount-associated ecosystem 9,10,[15][16][17][18][19] . The majority of seamounts do not cause the surface seamount effect because their summits are ...

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Section: Resultsmentioning

confidence: 96%

Bacterioplankton reveal years-long retention of Atlantic deep-ocean water by the Tropic Seamount

Giljan

Kamennaya

Otto³

et al. 2020

Sci Rep

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“…Each cuvette containing either live or autoclaved water was amended with one substrate to a concentration of 100 μ mol L −1 . This concentration has been used in enzymatic assays from other parts of the Arctic (Sala et al ; Arnosti ; Balmonte et al ), although substrate saturation curves with Svalbard fjord waters indicate that this concentration—while close to substrate saturating conditions—may underestimate V max of several enzymes by factors of 1.5–2.8 (Steen and Arnosti ). The high cost of the trypsin and chymotrypsin substrates in any case limit the use of these substrates at higher concentrations.…”

Section: Methodsmentioning

confidence: 99%

“…In this study, we investigated the enzymatic capabilities of microbial communities to hydrolyze a range of organic substrates in Tyrolerfjord‐Young Sound, a fjord in northeast Greenland in which a decrease in salinity has been observed (Sejr et al ). We used a suite of structurally diverse peptide, glucose, and polysaccharide substrates, the hydrolytic enzymes for which have been found active in a range of freshwater (Murrell et al ; Stepanauskas et al ) and marine environments (Obayashi and Suzuki ; Arnosti et al ; Balmonte et al ; Balmonte et al ). Moreover, these substrates and their constituent monomers comprise a substantial fraction of aquatic OM pool (Benner ).…”

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confidence: 99%

Sharp contrasts between freshwater and marine microbial enzymatic capabilities, community composition, and DOM pools in a NE Greenland fjord

Balmonte

Hasler-Sheetal

Glud

et al. 2019

Limnology & Oceanography

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Increasing glacial discharge can lower salinity and alter organic matter (OM) supply in fjords, but assessing the biogeochemical effects of enhanced freshwater fluxes requires understanding of microbial interactions with OM across salinity gradients. Here, we examined microbial enzymatic capabilities—in bulk waters (nonsize‐fractionated) and on particles (≥ 1.6 μm)—to hydrolyze common OM constituents (peptides, glucose, polysaccharides) along a freshwater–marine continuum within Tyrolerfjord‐Young Sound. Bulk peptidase activities were up to 15‐fold higher in the fjord than in glacial rivers, whereas bulk glucosidase activities in rivers were twofold greater, despite fourfold lower cell counts. Particle‐associated glucosidase activities showed similar trends by salinity, but particle‐associated peptidase activities were up to fivefold higher—or, for several peptidases, only detectable—in the fjord. Bulk polysaccharide hydrolase activities also exhibited freshwater–marine contrasts: xylan hydrolysis rates were fivefold higher in rivers, while chondroitin hydrolysis rates were 30‐fold greater in the fjord. Contrasting enzymatic patterns paralleled variations in bacterial community structure, with most robust compositional shifts in river‐to‐fjord transitions, signifying a taxonomic and genetic basis for functional differences in freshwater and marine waters. However, distinct dissolved organic matter (DOM) pools across the salinity gradient, as well as a positive relationship between several enzymatic activities and DOM compounds, indicate that DOM supply exerts a more proximate control on microbial activities. Thus, differing microbial enzymatic capabilities, community structure, and DOM composition—interwoven with salinity and water mass origins—suggest that increased meltwater may alter OM retention and processing in fjords, changing the pool of OM supplied to coastal Arctic microbial communities.

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“…The assemblage of enzymes that a microbial community can produce affects the nature and quantity of organic substrates that microbial communities can access, as well as the rates at which they are hydrolyzed (Arnosti, 2011). These functional patterns follow gradients across depth (Baltar et al, 2010b;Steen et al, 2012;Hoarfrost and Arnosti, 2017), latitude (Arnosti et al, 2011), hydrographic properties (Baltar and Arístegui, 2017;Hoarfrost and Arnosti, 2017;Balmonte et al, 2018), and between coastal and open ocean regions (D'Ambrosio et al, 2014).…”

Section: Introductionmentioning

confidence: 99%

Gulf Stream Ring Water Intrusion on the Mid-Atlantic Bight Continental Shelf Break Affects Microbially Driven Carbon Cycling

et al. 2019

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Warm core, anticyclonic rings that spin off from the Gulf Stream circulate through the region directly offshore of the Mid-Atlantic Bight. If a warm core ring reaches the continental shelf break, its warm, highly saline water may subduct under cooler, fresher continental shelf surface water, resulting in subsurface waters at the shelf break and over the upper continental slope with high temperatures and salinities and distinct physical and chemical properties characteristic of Gulf Stream water. Such intruding water may also have microbial communities with distinct functional capacities, which may in turn affect the rate and nature of carbon cycling in this coastal/shelf environment. However, the functional capabilities of microbial communities within ring intrusion waters relative to surrounding continental shelf waters are largely unexplored. We investigated microbial community capacity to initiate organic matter remineralization by measuring hydrolysis of a suite of polysaccharide, peptide, and glucose substrates along a transect oriented across the Mid-Atlantic Bight shelf, shelf break, and upper slope. At the outermost sampling site, warm and salty water derived from a Gulf Stream warm core ring was present in the lower portion of the water column. This water exhibited hydrolytic capacities distinct from other sampling sites, and exhibited lower heterotrophic bacterial productivity overall. Warm core rings adjacent to the Mid-Atlantic Bight shelf have increased in frequency and duration in recent years. As the influence of warm core rings on the continental shelf and slope increases in the future, the rate and nature of organic matter remineralization on the continental shelf may also shift.

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Structure and function of high Arctic pelagic, particle‐associated and benthic bacterial communities

Cited by 40 publications

References 72 publications

Bacterioplankton reveal years-long retention of Atlantic deep-ocean water by the Tropic Seamount

Bacterioplankton reveal years-long retention of Atlantic deep-ocean water by the Tropic Seamount

Sharp contrasts between freshwater and marine microbial enzymatic capabilities, community composition, and DOM pools in a NE Greenland fjord

Gulf Stream Ring Water Intrusion on the Mid-Atlantic Bight Continental Shelf Break Affects Microbially Driven Carbon Cycling

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