Susanne Logemann scite author profile

With the increased use of chemical fertilizers in agriculture, many densely populated countries face environmental problems associated with high ammonia emissions. The process of anaerobic ammonia oxidation ('anammox') is one of the most innovative technological advances in the removal of ammonia nitrogen from waste water. This new process combines ammonia and nitrite directly into dinitrogen gas. Until now, bacteria capable of anaerobically oxidizing ammonia had never been found and were known as "lithotrophs missing from nature". Here we report the discovery of this missing lithotroph and its identification as a new, autotrophic member of the order Planctomycetales, one of the major distinct divisions of the Bacteria. The new planctomycete grows extremely slowly, dividing only once every two weeks. At present, it cannot be cultivated by conventional microbiological techniques. The identification of this bacterium as the one responsible for anaerobic oxidation of ammonia makes an important contribution to the problem of unculturability.

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The anaerobic oxidation of ammonium

Jetten

et al. 1998

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From recent research it has become clear that at least two different possibilities for anaerobic ammonium oxidation exist in nature. 'Aerobic' ammonium oxidizers like Nitrosomonas eutropha were observed to reduce nitrite or nitrogen dioxide with hydroxylamine or ammonium as electron donor under anoxic conditions. The maximum rate for anaerobic ammonium oxidation was about 2 nmol NH4+ min-1 (mg protein)-1 using nitrogen dioxide as electron acceptor. This reaction, which may involve NO as an intermediate, is thought to generate energy sufficient for survival under anoxic conditions, but not for growth. A novel obligately anaerobic ammonium oxidation (Anammox) process was recently discovered in a denitrifying pilot plant reactor. From this system, a highly enriched microbial community with one dominating peculiar autotrophic organism was obtained. With nitrite as electron acceptor a maximum specific oxidation rate of 55 nmol NH4+ min-1 (mg protein)-1 was determined. Although this reaction is 25-fold faster than in Nitrosomonas, it allowed growth at a rate of only 0.003 h-1 (doubling time 11 days). 15N labeling studies showed that hydroxylamine and hydrazine were important intermediates in this new process. A novel type of hydroxylamine oxidoreductase containing an unusual P468 cytochrome has been purified from the Anammox culture. Microsensor studies have shown that at the oxic/anoxic interface of many ecosystems nitrite and ammonia occur in the absence of oxygen. In addition, the number of reports on unaccounted high nitrogen losses in wastewater treatment is gradually increasing, indicating that anaerobic ammonium oxidation may be more widespread than previously assumed. The recently developed nitrification systems in which oxidation of nitrite to nitrate is prevented form an ideal partner for the Anammox process. The combination of these partial nitrification and Anammox processes remains a challenge for future application in the removal of ammonium from wastewater with high ammonium concentrations.

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Influence of temperature on biological phosphorus removal: process and molecular ecological studies

et al. 1998

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Molecular microbial diversity in a nitrifying reactor system without sludge retention

Logemann

1998

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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 (35³C) 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. z

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Untitled

et al. 1997

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Some aspects of inorganic nitrogen conversion by microorganisms like N2O emission and hydroxylamine metabolism studied by Beijerinck and Kluyver, founders of the Delft School of Microbiology, are still actual today. In the Kluyver Laboratory for Biotechnology, microbial conversion of nitrogen compounds is still a central research theme. In recent years a range of new microbial processes and process technological applications have been studied. This paper gives a review of these developments including, aerobic denitrification, anaerobic ammonium oxidation, heterotrophic nitrification, and formation of intermediates (NO2-, NO, N2O), as well as the way these processes are controlled at the genetic and enzyme level.

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