Comparison of Oxidation Kinetics of Nitrite-Oxidizing Bacteria: Nitrite Availability as a Key Factor in Niche Differentiation

Nowka, Boris; Daims, Holger; Spieck, Eva

doi:10.1128/aem.02734-14

Cited by 292 publications

(239 citation statements)

References 75 publications

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“…In particular, the specific rates for AOAs range from 11 to 24 μg N mg − 1 protein h − 1 (Kim et al, 2012), whereas reported rates for Nitrospira spp. range between 16 and 42 μg N mg − 1 protein h − 1 (Nowka et al, 2015). Interesting differences in substrate/product tolerances were observed.…”

Section: Discussionmentioning

confidence: 97%

A robust nitrifying community in a bioreactor at 50 °C opens up the path for thermophilic nitrogen removal

et al. 2016

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The increasing production of nitrogen-containing fertilizers is crucial to meet the global food demand, yet high losses of reactive nitrogen associated with the food production/consumption chain progressively deteriorate the natural environment. Currently, mesophilic nitrogen-removing microbes eliminate nitrogen from wastewaters. Although thermophilic nitrifiers have been separately enriched from natural environments, no bioreactors are described that couple these processes for the treatment of nitrogen in hot wastewaters. Samples from composting facilities were used as inoculum for the batch-wise enrichment of thermophilic nitrifiers (350 days). Subsequently, the enrichments were transferred to a bioreactor to obtain a stable, high-rate nitrifying process (560 days). The community contained up to 17% ammonia-oxidizing archaea (AOAs) closely related to 'Candidatus Nitrososphaera gargensis', and 25% nitrite-oxidizing bacteria (NOBs) related to Nitrospira calida. Incorporation of 13 C-derived bicarbonate into the respective characteristic membrane lipids during nitrification supported their activity as autotrophs. Specific activities up to 198 ± 10 and 894 ± 81 mg N g − 1 VSS per day for AOAs and NOBs were measured, where NOBs were 33% more sensitive to free ammonia. The NOBs were extremely sensitive to free nitrous acid, whereas the AOAs could only be inhibited by high nitrite concentrations, independent of the free nitrous acid concentration. The observed difference in product/substrate inhibition could facilitate the development of NOB inhibition strategies to achieve more cost-effective processes such as deammonification. This study describes the enrichment of autotrophic thermophilic nitrifiers from a nutrient-rich environment and the successful operation of a thermophilic nitrifying bioreactor for the first time, facilitating opportunities for thermophilic nitrogen removal biotechnology.

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Section: Discussionmentioning

confidence: 97%

A robust nitrifying community in a bioreactor at 50 °C opens up the path for thermophilic nitrogen removal

et al. 2016

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“…So far, investigations on nitrite oxidation kinetics have mainly been based on non-marine pure cultures, enrichment cultures, or natural assembles (Prosser 1989, Both et al 1992, Laanbroek et al 1994, Schramm et al 1999, Blackburne et al 2007, Nowka et al 2015. The aim of this study was to investigate the substrate affinity of marine NOB to link it to environmental conditions and nitrite oxidation kinetics, which thus far has been difficult because nitrite affinity of marine NOB had not yet been investigated in pure cultures.…”

Section: Nitrite Oxidation Kineticsmentioning

confidence: 99%

“…Nitrite oxidation kinetics were calculated based on activity measurements performed after Nowka et al (2015). Nitrospira sp.…”

Section: Activity Measurements and Calculation Of Nitrite Oxidation Kmentioning

confidence: 99%

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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“…Analyses of Nitrobacter genome sequences provided first insights into the genomic makeup of NOB and revealed a greater metabolic flexibility than anticipated earlier, which included the mixotrophic utilization of various organic substrates (8,9). However, Nitrobacter require high nitrite concentrations (10,11), and molecular surveys indicated that Nitrobacter are not the primary NOB in ecosystems with low ambient nitrite levels such as unfertilized soils (12), freshwater habitats (13), and most WWTPs (14).…”

mentioning

confidence: 99%

“…Nitrospira are well adapted to low nitrite concentrations (10,11) and form at least six phylogenetic lineages (15,16) that are globally distributed in soils (17,18), the oceans (19), freshwater habitats (20), hot springs (16), and many other oxic habitats (15). In addition, Nitrospira members are the key NOB in most WWTPs (14,15).…”

mentioning

confidence: 99%

Expanded metabolic versatility of ubiquitous nitrite-oxidizing bacteria from the genus Nitrospira

Koch

Lücker

Albertsen

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

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472

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Nitrospira are a diverse group of nitrite-oxidizing bacteria and among the environmentally most widespread nitrifiers. However, they remain scarcely studied and mostly uncultured. Based on genomic and experimental data from Nitrospira moscoviensis representing the ubiquitous Nitrospira lineage II, we identified ecophysiological traits that contribute to the ecological success of Nitrospira. Unexpectedly, N. moscoviensis possesses genes coding for a urease and cleaves urea to ammonia and CO2. Ureolysis was not observed yet in nitrite oxidizers and enables N. moscoviensis to supply ammonia oxidizers lacking urease with ammonia from urea, which is fully nitrified by this consortium through reciprocal feeding. The presence of highly similar urease genes in Nitrospira lenta from activated sludge, in metagenomes from soils and freshwater habitats, and of other ureases in marine nitrite oxidizers, suggests a wide distribution of this extended interaction between ammonia and nitrite oxidizers, which enables nitrite-oxidizing bacteria to indirectly use urea as a source of energy. A soluble formate dehydrogenase lends additional ecophysiological flexibility and allows N. moscoviensis to use formate, with or without concomitant nitrite oxidation, using oxygen, nitrate, or both compounds as terminal electron acceptors. Compared with Nitrospira defluvii from lineage I, N. moscoviensis shares the Nitrospira core metabolism but shows substantial genomic dissimilarity including genes for adaptations to elevated oxygen concentrations. Reciprocal feeding and metabolic versatility, including the participation in different nitrogen cycling processes, likely are key factors for the niche partitioning, the ubiquity, and the high diversity of Nitrospira in natural and engineered ecosystems.

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Comparison of Oxidation Kinetics of Nitrite-Oxidizing Bacteria: Nitrite Availability as a Key Factor in Niche Differentiation

Cited by 292 publications

References 75 publications

A robust nitrifying community in a bioreactor at 50 °C opens up the path for thermophilic nitrogen removal

A robust nitrifying community in a bioreactor at 50 °C opens up the path for thermophilic nitrogen removal

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

Expanded metabolic versatility of ubiquitous nitrite-oxidizing bacteria from the genus Nitrospira

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