Five mixed samples prepared from the surface sediments of 20 north-east Mongolian soda lakes with total salt contents from 5 to 360 g/l and pH values from 9.7 to 10.5 were used to enrich for ...alkaliphilic ammonia-oxidizing bacteria. Successful enrichments at pH 10 were achieved on carbonate mineral medium containing 0.6 M total Na(+) and < or =4 mM NH(4)Cl. Five isolates (ANs1-ANs5) of ammonia-oxidizing bacteria capable of growth at pH 10 were obtained from the colonies developed on bilayered gradient plates. The cells were motile and coccoid, with well-developed intracytoplasmic membranes (ICPM) and carboxysomes. At pH 10.0, ammonia was toxic for growth at concentrations higher than 5 mM NH(4)Cl. The bacteria were able to grow within the salinity range of 0.1-1.0 M of total Na+ (optimum 0.3 M). In media containing 0.3-0.6 M total Na(+), optimal growth in batch cultures occurred in the presence of a bicarbonate/carbonate buffer system within the pH range 8.5-9.5, with the highest pH limit at pH 10.5. At pH lower than 8.0, growth was slower, most probably due to decreasing free ammonia. The pH profile of the respiratory activity was broader, with limits at 6.5-7.0 and 11.0 and an optimum at 9.5-10.0. In pH-controlled, NH(3)-limited continuous culture, isolate ANs5 grew up to pH 11.3, which is the highest pH limit known for ammonia-oxidizing bacteria so far. This showed the existence of extremely alkali-tolerant ammonia-oxidizing bacteria in the soda lakes. Comparative 16S rDNA sequence analysis of the five isolates demonstrated that they possess identical 16S rDNA genes and that they are closely related to Nitrosomonas halophila (sequence similarity 99.3%), a member of the beta-subclass of the Proteobacteria. This affiliation was confirmed by comparative sequence analysis of the amoA gene, encoding the active-site subunit of the ammonia-monoxygenase, of one of the isolates. DNA-DNA hybridization data further supported that the soda lake isolates are very similar to each other and represent an alkali-tolerant subpopulation of N. halophila whose species description is herewith amended.
Recently, the single reactor system for high activity ammonia removal over nitrite (SHARON) process was developed for the removal of ammonia from wastewater with high ammonia concentrations. In ...contrast to normal systems, this nitrifying reactor system is operated at relatively high temperatures (35°C) without sludge retention. Classical methods to describe the microbial community present in the reactor failed and, therefore, the microorganisms responsible for ammonia removal in this single reactor system were investigated using several complementary molecular biological techniques. The results obtained via these molecular methods were in good agreement with each other and demonstrated successful monitoring of microbial diversity. Denaturing gradient gel electrophoresis of 16S rRNA PCR products proved to be an effective technique to estimate rapidly the presence of at least four different types of bacteria in the SHARON reactor. In addition, analysis of a 16S rRNA gene library revealed that there was one dominant (69%) clone which was highly similar (98.8%) to
Nitrosomonas eutropha. Of the other clones, 14% could be assigned to new members of the
Cytophaga/Flexibacter group. These data were qualitatively and quantitatively confirmed by two independent microscopic methods. The presence of about 70% ammonia oxidizing bacteria was demonstrated using a fluorescent oligonucleotide probe (NEU) targeted against the 16S rRNA of the
Nitrosomonas cluster. Electron microscopic pictures showed the typical morphology of ammonia oxidizers in the majority of the cells from the SHARON reactor.
Abstract
Recently, the single reactor system for high activity ammonia removal over nitrite (SHARON) process was developed for the removal of ammonia from wastewater with high ammonia concentrations. ...In contrast to normal systems, this nitrifying reactor system is operated at relatively high temperatures (35°C) without sludge retention. Classical methods to describe the microbial community present in the reactor failed and, therefore, the microorganisms responsible for ammonia removal in this single reactor system were investigated using several complementary molecular biological techniques. The results obtained via these molecular methods were in good agreement with each other and demonstrated successful monitoring of microbial diversity. Denaturing gradient gel electrophoresis of 16S rRNA PCR products proved to be an effective technique to estimate rapidly the presence of at least four different types of bacteria in the SHARON reactor. In addition, analysis of a 16S rRNA gene library revealed that there was one dominant (69%) clone which was highly similar (98.8%) to Nitrosomonas eutropha. Of the other clones, 14% could be assigned to new members of the Cytophaga/Flexibacter group. These data were qualitatively and quantitatively confirmed by two independent microscopic methods. The presence of about 70% ammonia oxidizing bacteria was demonstrated using a fluorescent oligonucleotide probe (NEU) targeted against the 16S rRNA of the Nitrosomonas cluster. Electron microscopic pictures showed the typical morphology of ammonia oxidizers in the majority of the cells from the SHARON reactor.
In order to meet increasingly stringentEuropean discharge standards, new applicationsand control strategies for the sustainableremoval of ammonia from wastewater have to beimplemented. In this paper ...we discuss anitrogen removal system based on the processesof partial nitrification and anoxic ammoniaoxidation (anammox). The anammox process offersgreat opportunities to remove ammonia in fullyautotrophic systems with biomass retention. Noorganic carbon is needed in such nitrogenremoval system, since ammonia is used aselectron donor for nitrite reduction. Thenitrite can be produced from ammonia inoxygen-limited biofilm systems or in continuousprocesses without biomass retention. Forsuccessful implementation of the combinedprocesses, accurate biosensors for measuringammonia and nitrite concentrations, insight inthe complex microbial communities involved, andnew control strategies have to be developed andevaluated.PUBLICATION ABSTRACT