Metabolic strategies of free-living and aggregate-associated bacterial communities inferred from biologic and chemical profiles in the Black Sea suboxic zone

Fuchsman, Clara A.; Kirkpatrick, John B.; Brazelton, William J.; Murray, James; Staley, James T.

doi:10.1111/j.1574-6941.2011.01189.x

Cited by 101 publications

(185 citation statements)

References 79 publications

(138 reference statements)

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“…comm.). The use of such a lower isotope effect may be appropriate because other OMZ regions (like the eastern tropical North Pacific off Costa Rica OMZ, the Namibian OMZ, the Black Sea OMZ, and the Baltic Sea; Labrenz et al 2007, Fuchsman et al 2011, Füssel et al 2012, Spieck et al 2014, Buchwald et al 2015) host predominantly Nitrospina, for which we find a low isotope effect in this study. This shows that a more accurate assessment of isotope effects and the kinetic parameters that determine these effects is urgently needed to better constrain biogeochemical models.…”

Section: Environmental Relevance and Model Applicationmentioning

confidence: 67%

Oxidation kinetics and inverse isotope effect of marine nitrite-oxidizing isolates

Jacob¹,

Nowka²,

Merten³

et al. 2017

Aquat. Microb. Ecol.

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Nitrification, the step-wise oxidation of ammonium to nitrite and nitrate, is important in the marine environment because it produces nitrate, the most abundant marine dissolved inorganic nitrogen (DIN) component and N-source for phytoplankton and microbes. This study focused on the second step of nitrification, which is carried out by a distinct group of organisms, nitrite-oxidizing bacteria (NOB). The growth of NOB is characterized by nitrite oxidation kinetics, which we investigated for 4 pure cultures of marine NOB (Nitrospina watsonii 347, Nitrospira sp. Ecomares 2.1, Nitrococcus mobilis 231, and Nitrobacter sp. 311). We further compared the kinetics to those of non-marine species because substrate concentrations in marine environments are comparatively low, which likely influences kinetics and highlights the importance of this study. We also determined the isotope effect during nitrite oxidation of a pure culture of Nitrospina (Nitrospina watsonii 347) belonging to one of the most abundant marine NOB genera, and for a Nitrospira strain (Nitrospira sp. Ecomares 2.1). The enzyme kinetics of nitrite oxidation, described by Michaelis-Menten kinetics, of 4 marine genera are rather narrow and fall in the low end of halfsaturation constant (K m ) values reported so far, which span over 3 orders of magnitude between 9 and >1000 μM NO 2 − . Nitrospina has the lowest K m (19 μM NO 2 − ), followed by Nitrobacter (28 μM NO 2 − ), Nitrospira (54 μM NO 2 − ), and Nitrococcus (120 μM NO 2 − ). The isotope effects during nitrite oxidation by Nitrospina watsonii 347 and Nitrospira sp. Ecomares 2.1 were 9.7 ± 0.8 and 10.2 ± 0.9 ‰, respectively. This confirms the inverse isotope effect of NOB described in other studies; however, it is at the lower end of reported isotope effects. We speculate that differences in isotope effects reflect distinct nitrite oxidoreductase (NXR) enzyme orientations.

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Section: Environmental Relevance and Model Applicationmentioning

confidence: 67%

Oxidation kinetics and inverse isotope effect of marine nitrite-oxidizing isolates

Jacob¹,

Nowka²,

Merten³

et al. 2017

Aquat. Microb. Ecol.

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“…These aggregates, more commonly known as marine snow, contain microscale redoxclines under anoxic conditions (Alldredge and Cohen, 1987;Karl and Tilbrook, 1994;Woebken et al, 2007). Moreover, aggregate communities appear to be distinct from bulk water collected samples (Fuchsman et al, 2011). These communities were suggested to have active manganese reduction, sulfate reduction and sulfide oxidation at the interior of the aggregates.…”

Section: ) and Saanich Inlet In Canadamentioning

confidence: 99%

Water column biogeochemistry of oxygen minimum zones in the eastern tropical North Atlantic and eastern tropical South Pacific oceans

et al. 2016

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Abstract. Recent modeling results suggest that oceanic oxygen levels will decrease significantly over the next decades to centuries in response to climate change and altered ocean circulation. Hence, the future ocean may experience major shifts in nutrient cycling triggered by the expansion and intensification of tropical oxygen minimum zones (OMZs), which are connected to the most productive upwelling systems in the ocean. There are numerous feedbacks among oxygen concentrations, nutrient cycling and biological productivity; however, existing knowledge is insufficient to understand physical, chemical and biological interactions in order to adequately assess past and potential future changes.In the following, we summarize one decade of research performed in the framework of the Collaborative Research Center 754 (SFB754) focusing on climate-biogeochemistry interactions in tropical OMZs. We investigated the influence of low environmental oxygen conditions on biogeochemical cycles, organic matter formation and remineralization, greenhouse gas production and the ecology in OMZ regions of the eastern tropical South Pacific compared to the weaker OMZ of the eastern tropical North Atlantic. Based on our findings, a coupling of primary production and organic matter export via the nitrogen cycle is proposed, which may, however, be impacted by several additional factors, e.g., micronutrients, particles acting as microniches, vertical and horizontal transport of organic material and the role of zooplankton and viruses therein.

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“…In non-and less-eutrophic marine environments such as pristine estuaries and offshore waters, where the majority of the particles are biogenic and thus organically enriched (123), significantly different community structures of particle-associated and free-living microorganisms are commonly found (108,114,(127)(128)(129). Particle-associated bacterial communities are frequently enriched in the marine Roseobacter clade (MRC) bacteria of the Alphaproteobacteria; the Alteromonadaceae and Vibrionaceae groups of the Gammaproteobacteria; as well as the Deltaproteobacteria, Bacteroidetes, and Planctomycetes (108,127,(130)(131)(132)(133)(134)(135)(136)(137). Many of these bacteria produce extracellular enzymes for biopolymer degradation, and some require suboxic or anoxic microniches within particles to support microaerophilic or anaerobic metabolism.…”

Section: Physiological Challenges and Deleterious Effects Of Microbiamentioning

confidence: 99%

“…For example, in the oxygen minimum zone (OMZ) of the Eastern Tropical North Pacific, particles contribute 100% of the activity reducing nitrate to nitrite and 53 to 85% of N 2 production by denitrification and anammox (167). P cycling processes such as eDNA secretion (168,169) and particulate organic phosphorus degradation (153,170,171) are enhanced on marine particles, as are microbial S cycling activities such as sulfate reduction (133,141,147,153,172), sulfur oxidation (133,(146)(147)(148)153), and organic S compound (e.g., the algal osmolyte dimethylsulfoniopropionate [DMSP]) transformation and degradation (153,(173)(174)(175). As noted above, surface-and particle-associated microorganisms also contribute substantially to marine iron cycling processes, such as iron oxidation and reduction (78, 147, 176-178), siderophore-mediated iron solubilization and uptake (153,(179)(180)(181), iron transport among different oceanic environments (182), and biocorrosion (18, 69, 72, 81).…”

Section: Physiological Challenges and Deleterious Effects Of Microbiamentioning

confidence: 99%

Microbial Surface Colonization and Biofilm Development in Marine Environments

Dang

Lovell

2016

Microbiol Mol Biol Rev

870

636

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SUMMARYBiotic and abiotic surfaces in marine waters are rapidly colonized by microorganisms. Surface colonization and subsequent biofilm formation and development provide numerous advantages to these organisms and support critical ecological and biogeochemical functions in the changing marine environment. Microbial surface association also contributes to deleterious effects such as biofouling, biocorrosion, and the persistence and transmission of harmful or pathogenic microorganisms and their genetic determinants. The processes and mechanisms of colonization as well as key players among the surface-associated microbiota have been studied for several decades. Accumulating evidence indicates that specific cell-surface, cell-cell, and interpopulation interactions shape the composition, structure, spatiotemporal dynamics, and functions of surface-associated microbial communities. Several key microbial processes and mechanisms, including (i) surface, population, and community sensing and signaling, (ii) intraspecies and interspecies communication and interaction, and (iii) the regulatory balance between cooperation and competition, have been identified as critical for the microbial surface association lifestyle. In this review, recent progress in the study of marine microbial surface colonization and biofilm development is synthesized and discussed. Major gaps in our knowledge remain. We pose questions for targeted investigation of surface-specific community-level microbial features, answers to which would advance our understanding of surface-associated microbial community ecology and the biogeochemical functions of these communities at levels from molecular mechanistic details through systems biological integration.

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Metabolic strategies of free-living and aggregate-associated bacterial communities inferred from biologic and chemical profiles in the Black Sea suboxic zone

Cited by 101 publications

References 79 publications

Oxidation kinetics and inverse isotope effect of marine nitrite-oxidizing isolates

Oxidation kinetics and inverse isotope effect of marine nitrite-oxidizing isolates

Water column biogeochemistry of oxygen minimum zones in the eastern tropical North Atlantic and eastern tropical South Pacific oceans

Microbial Surface Colonization and Biofilm Development in Marine Environments

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