Microbial community composition and ultrastructure of granules from a full-scale anammox reactor.

Citation data:

Microbial ecology, ISSN: 1432-184X, Vol: 70, Issue: 1, Page: 118-31

Publication Year:
Usage 78
Abstract Views 74
Full Text Views 2
Link-outs 2
Captures 64
Readers 63
Exports-Saves 1
Social Media 1
Tweets 1
Citations 35
Citation Indexes 35
Repository URL:
Gonzalez-Gil, Graciela; Sougrat, Rachid; Behzad, Ali Reza; Lens, Piet Nl L; Saikaly, Pascal
Springer Nature; Springer Science + Business Media; Springer Verlag
Agricultural and Biological Sciences; Environmental Science; Anammox; Autotrophic denitrification; Granular sludge; Granules; Heterotrophic denitrification; Microbial aggregates; Polygon-shaped bacteria; Pyrosequencing
Most Recent Tweet View All Tweets
article description
Granules in anammox reactors contain besides anammox bacteria other microbial communities whose identity and relationship with the anammox bacteria are not well understood. High calcium concentrations are often supplied to anammox reactors to obtain sufficient bacterial aggregation and biomass retention. The aim of this study was to provide the first characterization of bacterial and archaeal communities in anammox granules from a full-scale anammox reactor and to explore on the possible role of calcium in such aggregates. High magnification imaging using backscattered electrons revealed that anammox bacteria may be embedded in calcium phosphate precipitates. Pyrosequencing of 16S rRNA gene fragments showed, besides anammox bacteria (Brocadiacea, 32%), substantial numbers of heterotrophic bacteria Ignavibacteriacea (18%) and Anaerolinea (7%) along with heterotrophic denitrifiers Rhodocyclacea (9%), Comamonadacea (3%), and Shewanellacea (3%) in the granules. It is hypothesized that these bacteria may form a network in which heterotrophic denitrifiers cooperate to achieve a well-functioning denitrification system as they can utilize the nitrate intrinsically produced by the anammox reaction. This network may provide a niche for the proliferation of archaea. Hydrogenotrophic methananogens, which scavenge the key fermentation product H2, were the most abundant archaea detected. Cells resembling the polygon-shaped denitrifying methanotroph Candidatus Methylomirabilis oxyfera were observed by electron microscopy. It is hypothesized that the anammox process in a full-scale reactor triggers various reactions overall leading to efficient denitrification and a sink of carbon as biomass in anammox granules.