The phylogeny of autotrophic ammonia-oxidizing bacteria as determined by analysis of 16S ribosomal RNA gene sequences

Head, Ian M.; Hiorns, WD; Embley, T. Martin; McCarthy, AJ; Saunders,

doi:10.1099/00221287-139-6-1147

Cited by 347 publications

(249 citation statements)

References 26 publications

(24 reference statements)

Supporting

Mentioning

235

Contrasting

Unclassified

Order By: Relevance

“…Dominance of the AOB community by Nitrosospira has already been reported for soil environments (for example, Kowalchuk et al, 2000;Wheatley et al, 2003). Although the various Nitrosopira phylogenetic clusters have been shown to sometimes yield unstable tree topologies (Head et al, 1993;Purkhold et al, 2000), the assignation of the AOB clones to particular clusters in our study was found to be reliable, that is robust when comparing the assignation obtained with the three different treeing algorithms. The only exception was cluster 2 that was differentiated from cluster 3b only with the maximum likelihood method, but only eight sequences were affiliated to this 'cluster 2'.…”

Section: Phylogenetic Affiliation Of Dominant Aob Phylotypes Accordinsupporting

confidence: 60%

Effects of aboveground grazing on coupling among nitrifier activity, abundance and community structure

et al. 2007

View full text Add to dashboard Cite

The influence of switches in grassland management to or from grazing on the dynamics of nitrifier activity, as well as the abundance of ammonia-oxidizing bacteria, AOB and ammonia-oxidizing archeae, AOA, was analyzed for two years after changing management. Additionally community structure of AOB was surveyed. Four treatments were compared in mesocosms: grazing on previously grazed grassland (G-G); no grazing on ungrazed grassland (U-U); grazing on ungrazed grassland (U-G) and cessation of grazing on grazed grassland (G-U). Nitrifier activity and abundance were always higher for G-G than U-U treatments and AOB community structure differed between these treatments. AOA abundance was in the same range as AOB abundance and followed the same trend. Grazing led to a change in AOB community structure within o5 months and a subsequent (5-12 months) increase in nitrifier activity and abundance. In contrast, cessation of grazing led to a decrease in nitrifier activity and abundance within o5 months and to a later (5-12 months) change in AOB community structure. Activity in G-U and U-G was similar to that in U-U and G-G, respectively, after 12 months. Sequence analysis of 16S rRNA gene clones showed that AOB retrieved from soils fell within the Nitrosospira lineage and percentages of AOB related to known Nitrosospira groups were affected by grazing. These results demonstrate that AOB and AOA respond quickly to changes in management. The selection of nitrifiers adapted to novel environmental conditions was a prerequisite for nitrification enhancement in U-G, whereas nitrification decrease in G-U was likely due to a partial starvation and decrease in the abundance of nitrifiers initially present. The results also suggest that taxonomic affiliation does not fully infer functional traits of AOB.

show abstract

Section: Phylogenetic Affiliation Of Dominant Aob Phylotypes Accordinsupporting

confidence: 60%

Effects of aboveground grazing on coupling among nitrifier activity, abundance and community structure

et al. 2007

View full text Add to dashboard Cite

show abstract

“…On one hand, the close physical association is useful for energetic reasons: NOB are able to efficiently intercept the nitrite Head et al 1993;Teske et al 1994). The bacterial genera responsible for the oxidation of ammonia and nitrite are presumed to be predominantly the genera Nitrosomonas and Nitrobacter, both of which are chemolithoautotrophic members of the class Proteobacteria (Wheaton et al 1994).…”

Section: Biological Relationships Of Ammonia-oxidizing Bacteria and Nmentioning

confidence: 99%

Biological nitrogen removal with nitrification and denitrification via nitrite pathway

Peng

Zhu

2006

Appl Microbiol Biotechnol

515

230

View full text Add to dashboard Cite

Presently, the wastewater treatment practices can be significantly improved through the introduction of new microbial treatment technologies. To meet increasingly stringent discharge standards, new applications and control strategies for the sustainable removal of ammonium from wastewater have to be implemented. Partial nitrification to nitrite was reported to be technically feasible and economically favorable, especially when wastewater with high ammonium concentrations or low C/N ratios is treated. For successful implementation of the technology, the critical point is how to maintain partial nitrification of ammonium to nitrite. Partial nitrification can be obtained by selectively inhibiting nitrite oxidizing bacteria through appropriate regulation of the system's DO concentration, microbial SRT, pH, temperature, substrate concentration and load, operational and aeration pattern, and inhibitor. The review addressed the microbiology, its consequences for their application, the current status regarding application, and the future developments.

show abstract

“…Until recently, ammonia oxidation has been considered to be entirely mediated through activities of ammonia-oxidizing bacteria (AOB; Kowalchuk and Stephen, 2001). Cultivation-dependent (Head et al, 1993), and subsequently cultivation-independent studies (Stephen et al, 1996(Stephen et al, , 1998, had suggested that members of a distinct clade of b-proteobacteria were the primary biological agents of ammonia oxidation in soil. The narrow phylogenetic breadth of this group facilitated the design of primers to monitor AOB using both phylogenetic (rRNA) and functional gene (amoA encoding the a-subunit of the key enzyme ammonia monooxygenase) markers (Rotthauwe et al, 1997;Kowalchuk et al, 2000;Kowalchuk and Stephen, 2001).…”

Section: Introductionmentioning

confidence: 99%

Bacteria, not archaea, restore nitrification in a zinc-contaminated soil

et al. 2009

View full text Add to dashboard Cite

Biological ammonia oxidation had long been thought to be mediated solely by discrete clades of b-and c-proteobacteria (ammonia-oxidizing bacteria; AOB). However, ammonia-oxidizing Crenarchaeota (ammonia-oxidizing archaea; AOA) have recently been identified and proposed to be the dominant agents of ammonia oxidation in soils. Nevertheless, the dynamics of AOB versus AOA, and their relative contribution to soil ammonia oxidation and ecosystem functioning on stress and environmental perturbation, remain unknown. Using a 3-year longitudinal field study and the amoA gene as a molecular marker, we demonstrate that AOB, but not AOA, mediate recovery of nitrification after zinc (Zn) contamination. Pristine soils showed approximately equal amoA gene copy numbers and transcript levels for AOB and AOA. At an intermediate Zn dose (33.7 mmol Zn per kg), ammonia oxidation was completely inhibited, and the numbers of AOB and AOA amoA gene copies and gene transcripts were reduced. After 2 years, ammonia oxidation in the field soils was fully restored to preexposure levels, and this restoration of function was concomitant with an increase of AOB amoA gene copy and gene transcript numbers. Analysis of the restored community revealed domination by a phylogenetically distinct Zn-tolerant Nitrosospira sp. community. In contrast, the numbers of AOA amoA gene copies and gene transcripts remained 3-and 10 4 -fold lower than recovered AOB values, respectively. Thus, although recent findings have emphasized a dominant role of archaea in soil-borne ammonia oxidation, we demonstrate that a phylogenetic shift within the AOB community drives recovery of nitrification from Zn contamination in this soil.

show abstract

The phylogeny of autotrophic ammonia-oxidizing bacteria as determined by analysis of 16S ribosomal RNA gene sequences

Cited by 347 publications

References 26 publications

Effects of aboveground grazing on coupling among nitrifier activity, abundance and community structure

Effects of aboveground grazing on coupling among nitrifier activity, abundance and community structure

Biological nitrogen removal with nitrification and denitrification via nitrite pathway

Bacteria, not archaea, restore nitrification in a zinc-contaminated soil

Contact Info

Product

Resources

About